KR102492308B1 - Electronic thermometer and calibrating temperature values method thereof - Google Patents

Abstract

The present invention relates to an electronic thermometer and a temperature value correction method of the electronic thermometer, and more particularly, to a temperature value correction method of a thermometer capable of providing more accurate temperature information to a user through temperature value correction of the thermometer.

Description

Electronic thermometer and temperature value correction method of electronic thermometer {ELECTRONIC THERMOMETER AND CALIBRATING TEMPERATURE VALUES METHOD THEREOF}

The present invention relates to an electronic thermometer and a temperature value correction method of the electronic thermometer, and more particularly, to a temperature value correction method of a thermometer capable of providing more accurate temperature information to a user through temperature value correction of the electronic thermometer. .

When it is necessary to frequently check the body temperature of a patient or infant, it is inconvenient for a guardian or medical staff to directly check the body temperature using a thermometer whenever necessary. A portable thermometer has been proposed as a way to solve these inconveniences, and the miniaturized portable thermometer has the advantage of being easily carried by a subject to measure body temperature, thereby enhancing convenience.

On the other hand, such a portable thermometer may be configured as an electronic thermometer equipped with a display device or a wireless communication function to provide better convenience to users. However, electronic thermometers require circuitry that processes data or supplies power, and in miniaturized electronic thermometers, the heat generated from these circuits affects the temperature sensor located close to the circuitry, so the accuracy of temperature measurement is compromised. There are issues with this that can fall off.

In addition, in relation to the above-described problem, a method such as adding a thermal insulation configuration to the electronic thermometer can be considered in order to minimize the effect of heat generation of the circuit part or the external temperature on the temperature sensor, but when including the thermal insulation configuration, the electronic thermometer difficulties in miniaturization design.

Korean Patent Publication No. 10-2020-0032331

The present invention has been devised to solve the above problems, and after separately providing a circuit part temperature sensor for measuring the temperature of the circuit part in the circuit part of the electronic thermometer, the temperature sensor previously provided according to the first to third temperature correction steps And to provide an electronic thermometer and a temperature value correction method of the electronic thermometer capable of solving the thermal interference problem of the miniaturized electronic thermometer by correcting the temperature value generated by the circuit part temperature sensor.

An electronic thermometer according to an embodiment of the present invention may include a temperature sensor and a circuit unit, the temperature sensor generates a first temperature value based on the temperature of a temperature measurement object, and the circuit unit is based on the temperature of the circuit unit a circuit unit temperature sensor configured to generate a second temperature value; and a calculator configured to calculate a temperature value of the temperature measurement object based on the generated first and second temperature values.

In one embodiment, the circuit unit includes first error data derived based on a difference between temperature values generated by the temperature sensor in a thermally insulated state with the circuit unit for each changing temperature value of the temperature measurement object, and the circuit unit changes Second error data derived based on a difference between temperature values generated by the temperature sensor of the circuit part for each temperature value and third error data derived based on the temperature value generated by the temperature sensor for each changing temperature value of the circuit part A storage unit to be stored; may be included.

In one embodiment, the calculator may correct the generated first temperature value by using a first correction constant included in the stored first error data.

In one embodiment, the calculation unit may correct the generated second temperature value by using a second correction constant included in the stored second error data.

In an embodiment, the calculation unit may calculate the temperature value of the temperature measurement object by recalibrating the corrected first temperature value using a third correction constant included in the stored third error data.

A temperature value correction method of an electronic thermometer according to an embodiment of the present invention includes a first temperature value correction step of correcting a first temperature value generated by the temperature sensor based on the temperature of a temperature measurement target; a second temperature value correction step of correcting a second temperature value generated by a circuit unit temperature sensor based on the temperature of the circuit unit; and a third temperature value correcting step of calculating the temperature value of the temperature measurement target by recalibrating the corrected first temperature value based on the first and second temperature values corrected through the first and second temperature correcting steps. ; can be included.

In one embodiment, the first temperature value correcting step may include deriving first error data based on a difference between temperature values generated by the temperature sensor in a thermally insulated state from the circuit unit for each changing temperature value of the temperature measurement object. step; and correcting the generated first temperature value using a first correction constant included in the derived first error data.

In one embodiment, the compensating the second temperature value may include deriving second error data based on a difference between temperature values generated by a temperature sensor of the circuit unit for each changing temperature value of the circuit unit; and correcting the generated second temperature value using a second correction constant included in the second error data.

In an embodiment, the third temperature value correcting step may include deriving third error data based on a temperature value generated by the temperature sensor for each changing temperature value of the circuit unit; and correcting the corrected first temperature value again using a third correction constant included in the third error data.

In one embodiment, the step of deriving the first to third error data may include deriving the error data by changing the temperature value of the temperature measurement target or circuit unit by a set unit temperature.

In one embodiment, the step of deriving the third error data changes the temperature value of the circuit unit by the set unit temperature for each case in which the temperature of the temperature measurement target is changed by the set unit temperature and derives error data. The step of doing; may include.

In one embodiment, the step of deriving error data by varying the set unit temperature by the set unit temperature may include deriving error data by using an interpolation method for temperature values between the set unit temperatures.

The electronic thermometer and the temperature value correction method of the electronic thermometer according to an embodiment of the present invention have an effect of providing accurate temperature information through temperature value correction even if the heat generated by the circuit part of the electronic thermometer interferes with the temperature sensor.

The electronic thermometer and the method for correcting the temperature value of the electronic thermometer according to an embodiment of the present invention have the advantage that the electronic thermometer does not need to have a separate thermal insulation configuration, and as the thermal insulation configuration is unnecessary, the electronic thermometer can be miniaturized and designed. there is.

1 is a block diagram showing the configuration of an electronic thermometer 100 according to an embodiment of the present invention.
2 is a block diagram showing the configuration of the circuit unit 120 of the electronic thermometer according to an embodiment of the present invention.
3 is a block diagram showing the configuration of the circuit unit 120 of the electronic thermometer according to an embodiment of the present invention in more detail.
4 to 7 are flowcharts illustrating a method of correcting a temperature value of an electronic thermometer according to an embodiment of the present invention.

The present invention will be described in detail with reference to the accompanying drawings. Here, repeated descriptions, well-known functions that may unnecessarily obscure the subject matter of the present invention, and detailed descriptions of configurations are omitted. Embodiments of the present invention are provided to more completely explain the present invention to those skilled in the art. Accordingly, the shapes and sizes of elements in the drawings may be exaggerated for clarity.

Throughout the specification, when a certain component is said to "include", it means that it may further include other components without excluding other components unless otherwise stated.

In addition, the term "unit" described in the specification means a unit that processes one or more functions or operations, which may be implemented as hardware or software or a combination of hardware and software.

1 is a block diagram showing the configuration of an electronic thermometer 100 according to an embodiment of the present invention.

Referring to FIG. 1 , an electronic thermometer 100 according to an embodiment of the present invention may include a temperature sensor 110 and a circuit unit 120.

The temperature sensor 110 is a component capable of generating information related to the temperature of a temperature measurement target when in contact with or close to a temperature measurement target (eg, a patient whose body temperature needs to be measured), and is an embodiment of the present invention. According to, the temperature sensor 110 may generate the first temperature value based on the temperature of the temperature measurement target.

In one embodiment, the temperature sensor 110 may include a thermistor element.

The circuit unit 120 may be located inside the electronic thermometer 100, and may include a circuit related to processing of all electrical signals handled by the electronic thermometer 100 and a power source for driving the electronic thermometer 100. can

2 is a block diagram showing the configuration of the circuit unit 120 of the electronic thermometer according to an embodiment of the present invention.

Referring to FIG. 2 , the circuit unit 120 of the electronic thermometer according to an embodiment of the present invention may include a circuit unit temperature sensor 121 and a calculation unit 122, and according to a preferred embodiment of the present invention A storage unit 123 may be further included.

The circuit part temperature sensor 121 is a component that is located inside the circuit part 120 and can generate information related to the temperature of the circuit part 120. According to an embodiment of the present invention, the circuit part temperature sensor 121 is a circuit part. A second temperature value may be generated based on the temperature of (120).

The calculation unit 122 may calculate the temperature value of the temperature measurement target based on the first temperature value generated by the temperature sensor 110 and the second temperature value generated by the circuit temperature sensor 121 .

In the storage unit 123, the first error data derived based on the difference between the temperature value generated by the circuit unit 120 and the temperature sensor 11 in a thermally insulated state for each changing temperature value of the temperature measurement object, the circuit unit ( Second error data derived based on the difference between the temperature values generated by the temperature sensor 121 of the circuit unit for each changing temperature value of 120) and the temperature generated by the temperature sensor 11 for each changing temperature value of the circuit unit 120 Third error data derived based on the difference between the values may be stored.

Here, according to a preferred embodiment of the present invention, the calculation unit 122 may use the first to third error data stored in the storage unit 123 to calculate the temperature value of the temperature measurement target.

In one embodiment, the calculation unit 122 may correct the first temperature value generated by the temperature sensor 110 by using a first correction constant included in the stored first error data.

Here, the first error data may be derived based on a difference between temperature values generated by the circuit unit 120 and the temperature sensor 110 in a thermally insulated state for each changing temperature value of the temperature measurement object.

In addition, the first error data may include a first correction constant, and the first correction constant is the temperature sensor 110 in a thermally insulated state from the circuit unit 120 for each changing temperature value of the temperature measurement target. It may mean a constant value for correcting a difference between generated temperature values.

For example, when the first temperature value generated by the temperature sensor 110 is 35°C when the actual temperature value of the temperature measurement target is 36°C, and the actual temperature value of the temperature measurement target is 37°C, the temperature sensor ( When the first temperature value generated by 110) is 36.5° C., the first correction constant may be 1 or 0.5 for each case.

In addition, according to a preferred embodiment of the present invention, the first error data may be derived by changing the temperature value of the actual temperature measurement object within a set temperature range and comparing it with the generated first temperature value, and the temperature range is It may be set based on a range in which a person's body temperature changes (eg, 30° C. to 45° C.).

In an embodiment, the calculation unit 122 may correct the second temperature value generated by the circuit part temperature sensor 121 by using the second correction constant included in the stored second error data.

Here, the second error data may be derived based on a difference between temperature values generated by the circuit unit temperature sensor 121 for each changing temperature value of the circuit unit 120 .

In addition, the second error data may include a second correction constant, and the second correction constant corrects a difference between temperature values generated by the circuit part temperature sensor 121 for each changing temperature value of the circuit part 120. It may mean a constant value for

For example, when the actual temperature value of the circuit unit 120 is 50°C, the second temperature value generated by the circuit unit temperature sensor 121 is 51°C, and the actual temperature value of the circuit unit 120 is 51°C, the temperature of the circuit unit When the second temperature value generated by the sensor 121 is 52.5° C., the second correction constant may be -1 or -1.5 in each case.

In addition, according to a preferred embodiment of the present invention, the second error data may be derived by changing the temperature value of the circuit unit 120 within a set temperature range and comparing it with the generated second temperature value, and the temperature range is the circuit unit It may be set based on the range in which the temperature of (120) changes (eg, 10 ° C to 80 ° C).

In an embodiment, the calculator 122 corrects the corrected first temperature value again using a third correction constant included in the stored third error data, thereby finally calculating the temperature value of the temperature measurement target. can do.

Here, the third error data may be derived based on a temperature value generated by the temperature sensor 110 for each changing temperature value of the circuit unit 120 .

In addition, the third error data may include a third correction constant, and the third correction constant is a temperature value generated by the temperature sensor 110 for each changing temperature value of the circuit unit 120 and the temperature measurement target. It may mean a constant value for correcting the difference between the temperatures of .

In an embodiment, in the process of deriving the first to third error data, the error data may be derived by changing the temperature value of the temperature measurement object or circuit unit 120 by a set unit temperature.

For example, the unit temperature may be set to 1°C, and in this case, error data may be derived through a process of changing the temperature value of the temperature measurement target or circuit unit 120 by 1°C.

In an embodiment, an interpolation method may be used for temperature values between the set unit temperatures, and error data for temperature values between the set unit temperatures may be derived through the interpolation method.

In addition, the third error data is not only the difference between the temperature value generated by the temperature sensor 110 and the temperature of the temperature measurement target for each changing temperature value of the circuit unit 120, but also the temperature of the circuit unit 120 is fixed and the temperature Cross measurement results for two temperature variables obtained by changing the temperature of the measurement target may be included. According to a preferred embodiment of the present invention, error data may be derived by changing the temperature value of the circuit unit 120 by the set unit temperature for each case where the temperature of the temperature measurement target is changed by the set unit temperature.

This intersection measurement method can be explained through Tables 1 and 2 below.

[Table 1]

[Table 2]

Referring to Tables 1 and 2, since the correction using the third correction constant is applied, the first and second temperature values generated by the temperature sensor 110 and the circuit part temperature sensor 121 are the first and second temperature values. It represents a value already corrected by the correction constant or the second correction constant. Accordingly, the temperature value generated by the temperature sensor 110 may be the same as the temperature of the temperature measurement object, excluding the effect of heat generated by the circuit unit 120 on the temperature sensor 110 . In addition, since the second temperature value generated by the circuit part temperature sensor 121 is a corrected value using the second correction constant, it may represent the same temperature value as the actual temperature of the circuit part 120 .

Referring to Tables 1 and 2, the difference between the temperature of the temperature measurement target and the corrected first temperature value may vary according to each temperature setting case, and the third correction constant may also vary according to each case.

In addition, according to a preferred embodiment of the present invention, the third error data is obtained by changing and comparing the temperature values of the temperature measurement target and the circuit unit 120 within a set temperature range for each of the temperature measurement target and the circuit unit 120. results can be derived.

As reviewed in the case above, the third error data may refer to data derived to determine the degree of influence of the heat generated in the circuit unit 120 on the temperature sensor 110, and is a preferred embodiment of the present invention. According to , the calculation unit 122 corrects the first temperature value and the second temperature value using the first and second correction constants included in the first and second error data, and then the second temperature value included in the third error data. The temperature value of the temperature measurement target may be finally calculated by re-correcting the corrected first temperature value using 3 correction constants, and as a result, the electronic thermometer 100 calculates the temperature value finally calculated by the calculator 122. can be provided to the user.

3 is a block diagram showing the configuration of the circuit unit 120 of the electronic thermometer 100 according to an embodiment of the present invention in more detail.

Referring to FIG. 3 , the circuit unit 120 of the electronic thermometer 100 according to an embodiment of the present invention includes a circuit unit temperature sensor 121, a calculation unit 122, and a storage unit 123, as well as an additional first ADC. 124, a second ADC 125 and a power supply unit 126 may be further included.

In one embodiment, the temperature sensor 110 may generate a first temperature value composed of analog data, and the first ADC 124 may convert the analog data received from the temperature sensor 110 into digital data. there is.

In one embodiment, the circuit part temperature sensor 121 may generate a second temperature value composed of analog data, and the second ADC 125 converts the analog data received from the circuit part temperature sensor 121 into digital data. can do.

Accordingly, the calculator 122 calculates the temperature value of the temperature measurement target based on the first temperature value and the second temperature value converted into digital data by the first ADC 124 and the second ADC 125. can

In one embodiment, the power supply 126 may supply the same power to each of the first ADC 124 and the second ADC 125 . At this time, since a deviation may occur between data converted by the ADC when each ADC is supplied with different power, it is preferable that each ADC is supplied with power from the same power supply source.

4 to 7 are flowcharts illustrating a method for correcting a temperature value of an electronic thermometer according to an embodiment of the present invention.

Referring to FIG. 4 , a method for correcting a temperature value of an electronic thermometer according to an embodiment of the present invention corrects a first temperature value generated by a temperature sensor 110 based on the temperature of an object to be measured. Step (S100), a second temperature value correction step (S200) of correcting the second temperature value generated by the circuit part temperature sensor 121 based on the temperature of the circuit part 120, and the first and second temperature correction steps A third temperature value correction step ( S300 ) of calculating the temperature value of the temperature measurement object by recalibrating the corrected first temperature value based on the first and second temperature values corrected through the above process.

Referring to FIG. 5 , in the first temperature value correction step (S100), the temperature measurement is performed based on the difference between the temperature value generated by the circuit unit 120 and the temperature sensor 110 in a thermally insulated state for each changing temperature value of the temperature measurement target. It may include deriving 1 error data (S110) and correcting the generated first temperature value using a first correction constant included in the derived first error data (S120).

Referring to FIG. 6 , in the second temperature value correction step (S200), second error data is derived based on a difference between temperature values generated by the circuit unit temperature sensor 121 for each changing temperature value of the circuit unit 120 ( S210) and correcting the generated second temperature value using a second correction constant included in the second error data (S220).

Referring to FIG. 7 , in the third temperature value correction step (S300), third error data is derived based on the temperature value generated by the temperature sensor 110 for each changing temperature value of the circuit unit 120 (S310), The corrected first temperature value may be further corrected using a third correction constant included in the third error data (S320).

The method for correcting the temperature value of the thermometer has been described with reference to the flow chart presented in the drawings. For simplicity, the method is shown and described as a series of blocks, but the invention is not limited to the order of the blocks, and some blocks may occur in a different order or concurrently with other blocks than shown and described herein. and various other branches, flow paths, and sequences of blocks that achieve the same or similar results may be implemented. Also, not all blocks shown may be required for implementation of the methods described herein.

Although the above has been described with reference to preferred embodiments of the present invention, those skilled in the art can variously modify and change the present invention within the scope not departing from the spirit and scope of the present invention described in the claims below. You will understand that it can be done.

100: electronic thermometer
110: temperature sensor
120: circuit part
121: circuit part temperature sensor
122: calculation unit
123: storage unit
124: first ADC
125: second ADC
126: power supply

Claims (12)

In the electronic thermometer including a temperature sensor and a circuit,
The temperature sensor,
Generating a first temperature value based on the temperature of the temperature measurement object;
The circuit part,
a circuit unit temperature sensor configured to generate a second temperature value based on the temperature of the circuit unit; and
A calculator configured to calculate a temperature value of the temperature measurement target based on the generated first and second temperature values;
The circuit part,
The first error data derived based on the difference between the temperature value generated by the circuit part and the temperature sensor in a thermally insulated state for each changing temperature value of the temperature measurement object, the circuit part temperature sensor for each changing temperature value of the circuit part A storage unit for storing second error data derived based on a difference between generated temperature values and third error data derived based on a temperature value generated by the temperature sensor for each changing temperature value of the circuit unit; and ,
The stored first error data is derived by changing the temperature value of the actual temperature measurement object within a set temperature range and comparing it with the generated first temperature value, and the circuit part and the heat for each changing temperature value of the temperature measurement object. A first correction constant that is a constant value for correcting a difference between temperature values generated by the temperature sensor in an insulated state,
The stored second error data is derived by changing the temperature value of the circuit part within a set temperature range and comparing it with the generated second temperature value, and the temperature value generated by the circuit part temperature sensor for each changing temperature value of the circuit part. A second correction constant that is a constant value for correcting the difference between
The stored third error data is obtained by changing the temperature of the temperature measurement target while fixing the difference between the temperature value generated by the temperature sensor and the temperature of the temperature measurement target for each changing temperature value of the circuit unit and the temperature of the circuit unit A constant value for correcting the difference between the temperature value generated by the temperature sensor and the temperature of the temperature measurement object for each changing temperature value of the circuit part, including a cross measurement result of two temperature variables, A third correction constant derived by cross-measuring 1 temperature value and the corrected second temperature value,
The calculator,
The generated first temperature value is corrected by adding the first correction constant to the generated first temperature value, and the generated second temperature value is corrected by adding the second correction constant to the generated second temperature value. And calculating the temperature value of the temperature measurement object by adding the third correction constant and correcting the corrected first temperature value again.
electronic thermometer.
delete delete delete delete A temperature value correction method of an electronic thermometer for increasing reliability of an electronic thermometer by correcting a temperature value error of an electronic thermometer including a temperature sensor and a circuit unit, the method comprising:
a first temperature value correction step of correcting a first temperature value generated by the temperature sensor based on the temperature of a temperature measurement target;
a second temperature value correction step of correcting a second temperature value generated by a circuit unit temperature sensor based on the temperature of the circuit unit; and
a third temperature value correcting step of calculating a temperature value of the temperature measurement object by recalibrating the corrected first temperature value based on the first and second temperature values corrected through the first and second temperature correcting steps; Including,
The first temperature value correction step,
First error data is derived based on a difference between temperature values generated by the circuit part and the temperature sensor in a thermally insulated state for each changing temperature value of the temperature measurement target, and the temperature of the actual temperature measurement target is within a set temperature range. deriving the first error data by changing a value and comparing the generated first temperature value; and
A first correction constant, which is a constant value for correcting a difference between the temperature values generated by the temperature sensor in a thermally insulated state from the circuit part, for each changing temperature value of the temperature measurement object included in the derived first error data Including; correcting the generated first temperature value in addition to the generated first temperature value,
The second temperature value correction step,
Second error data is derived based on a difference between temperature values generated by the circuit temperature sensor for each changing temperature value of the circuit, and the generated second temperature value is changed by changing the temperature value of the circuit within a set temperature range. deriving the second error data by comparing with ; and
A second correction constant, which is a constant value for correcting the difference between the temperature values generated by the temperature sensor of the circuit unit for each changing temperature value of the circuit unit, included in the second error data, is added to the generated second temperature value, Including; correcting the generated second temperature value,
The third temperature value correction step,
Third error data is derived based on the temperature value generated by the temperature sensor for each changing temperature value of the circuit unit, and the temperature value generated by the temperature sensor for each changing temperature value of the circuit unit and the temperature of the temperature measurement target deriving the third error data including a result of cross measurement of two temperature variables obtained by changing the temperature of the temperature measurement target while fixing the temperature of the circuit unit and the difference between the temperature of the circuit unit; and
A constant value for correcting a difference between the temperature value generated by the temperature sensor and the temperature of the temperature measurement target for each changing temperature value of the circuit part, included in the third error data, and the corrected first temperature value and Compensating the corrected first temperature value again by adding a third correction constant derived by cross-measuring the corrected second temperature value to the corrected first temperature value,
How to calibrate the temperature value of an electronic thermometer.
delete delete delete According to claim 6,
Deriving the first to third error data,
Characterized in that it comprises a; step of changing the temperature measurement object or the temperature value of the circuit unit by a set unit temperature and deriving error data.
How to calibrate the temperature value of an electronic thermometer.
According to claim 10,
The step of deriving the third error data,
and deriving error data by changing the temperature value of the circuit part by a set unit temperature for each case in which the temperature of the temperature measurement object is changed by the set unit temperature.
How to calibrate the temperature value of an electronic thermometer.
According to claim 10,
The step of deriving error data while changing by the set unit temperature,
Deriving error data using an interpolation method for temperature values between the set unit temperatures;
How to calibrate the temperature value of an electronic thermometer.

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